JP2006154558A - Entity microscope - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To observe each image of samples simultaneously with each of different magnifications. <P>SOLUTION: A first zoom handle shaft 40a and a second zoom handle shaft 40b are linked or released by tightening and loosening of a stop member 50 of a linking member 48, a second group lens 182a and a third group lens 183a and a second group lens 182b and a third group lens 183b are vertically transferred by linking or independently in response to each rotation of the first zoom handle shaft 40a and the second zoom handle shaft 40b. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a stereomicroscope that stereoscopically views a sample through a pair of observation optical axes.

  The stereomicroscope has independent optical systems for the left and right eyes, and allows the sample to be viewed stereoscopically by observing the same sample from different directions. This stereomicroscope is classified into an inner oblique type (Greeneau type) and a parallel type (Galileo type) according to the arrangement method of the optical axis of the objective lens. In the Greenough type, each optical axis of the variable magnification optical system arranged on the left and right is arranged to be inclined at an angle with respect to the sample. In the Galileo system, the optical axes of the objective lenses are arranged in parallel. These stereomicroscopes illuminate a sample with illumination light emitted from an epi-illumination device, form reflected light from this sample, that is, observation light, through each objective lens on the left and right, and form an observation image through each eyepiece. obtain.

  The magnification of the observation image is changed by changing both the focal lengths of the left and right variable magnification optical systems. In order to vary the focal length of each objective lens, it is necessary to relatively change the interval between the plurality of lenses constituting each objective lens. Actually, the focal length is varied and the imaging position is corrected by moving a plurality of lenses so that the imaging position does not change when the focal length of each objective lens is changed.

  Stereoscopic viewing of the sample occurs because there is a difference between the left and right parallaxes (parallax difference), and thus stereoscopic observation becomes impossible if the left and right magnifications are different. However, the stereomicroscope has a structure in which the left and right magnifications are always matched when the magnification is varied.

As a technique for arbitrarily changing the magnification, there are, for example, a zoom magnifying mechanism using a plate cam disclosed in Patent Document 1 and a zoom lens driving mechanism of a stereomicroscope disclosed in Patent Document 2. A zooming mechanism using a plate cam disclosed in Patent Document 1 performs zooming by moving a zoom moving lens arranged on the left and right by two plate cams provided on both sides of the zoom handle shaft in the vertical direction. Mechanism. The zoom lens driving mechanism of a stereomicroscope disclosed in Patent Document 2 is a mechanism that uses a cylindrical cam instead of a plate cam as a moving means of a zoom moving lens.
Utility Model Registration No. 2563633 No. 8-5448

  In recent years, with the advancement of image pickup apparatuses, it has become possible to easily pick up an observation image of a microscope with high definition using a TV (television) camera or a digital camera. In the fields of the industrial and medical / research markets, a microscope including a stereomicroscope is generally used for observing a sample. Recently, in addition to visual observation, images are often taken with a TV camera or a digital camera from the viewpoint of visibility, recordability, and ease.

  In the industrial field, for example, competition for development and sales of devices such as liquid crystal displays is intensifying. Accordingly, in the appearance inspection of devices and the like in production factories, improvement of inspection efficiency is always required in addition to ensuring quality. Under such circumstances, when inspecting the whole device and its details, the magnification of the microscope is set to a low magnification once to check the whole part, and then the magnification of the microscope is changed to a high magnification to detail details. It goes through two steps of confirmation.

  In order to further increase the inspection speed in such an inspection process, the operation of switching the magnification of the microscope from low to high is omitted, and inspection is performed at both low and high magnification at the moment when the device is placed on the stage. It is desirable to do.

  In the medical / research field, there is a demand to observe the shape and color of one biological specimen with a TV camera in real time at different magnifications.

  It is impossible to set two different magnifications simultaneously in a normal optical microscope having only one observation optical axis in response to the above requirements. In addition, a stereomicroscope having two observation optical axes on the left and right is originally intended for stereoscopic observation of the sample, so that the magnification of each of the left and right observation optical axes is variable in conjunction with each other. Therefore, it is not possible to set two different magnifications simultaneously.

  The present invention includes a first optical system having at least one lens movable in the first optical axis direction, a second optical system having at least one lens movable in the second optical axis direction, The stereomicroscope includes an interlocking switching mechanism that moves the first lens and the second lens in conjunction with each other and releases the interlocking to move independently.

  The present invention can provide a stereomicroscope that can simultaneously observe each image of a sample at different magnifications.

  Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.

  1 to 9 are configuration diagrams of a parallel (Galileo type) stereomicroscope. FIG. 1 is an overall side view, FIG. 2 is a front view, FIG. 3 is a configuration diagram of a zoom lens body, and FIG. 5 is a sectional view taken along the line BB in FIG. 3, FIG. 6 is a sectional view taken along the line DD in FIG. 3 at the lowest magnification, and FIG. 7 is a sectional view taken along the line DD in FIG. FIG. 8 is a front view of the left and right sides at the same magnification and the highest magnification. FIG. 9 is a front view of the left side at the lowest magnification and the right side at the highest magnification.

  The stereomicroscope 1 includes a stage 3 on which a sample 2 is placed as shown in FIG. 1, and an L-shaped gantry 4 is erected on the stage. A support arm 5 is provided on the gantry 4 so as to move up and down in response to a rotation operation of the focusing handle 6. A zoom mirror body 7 is supported on the support arm 5. This zoom lens body 7 has a lens frame 8, as shown in FIG. 2, provided with an attachment portion 10 for attaching a fixed objective lens 9 to the lower portion, and an attachment portion for attaching a lens barrel 11 to the upper portion. 12 is provided.

  In the fixed objective lens 9, lenses 13a and 13b are provided on the same optical axis. First and second eyepieces (left and right eyepieces) 14a and 14b are attached to the lens barrel 11, and first and second television cameras (left and right TV cameras) 15a and 15b are attached to the lens barrel 11. First and second TV camera ports 16a, (16b) are provided. The first and second TV cameras 15a and 15b have first and second imaging elements 17a and 17b, respectively.

The stereomicroscope 1 has a first optical axis L ₁ and a second optical axis L ₂ that are independent on both the left and right sides so that the sample 2 can be viewed stereoscopically from different directions as shown in FIG. . The first and the optical axis L ₁ second to the optical axis L _2, first and second eyepiece lens 14a, respectively, as parallel to one another within the microscope body frame 8 of the zoom lens body 7 from 14b, the fixed objective The light is collected so as to cross on the sample 2 through the lens 9.

The first optical axis _{L 1,} the fixed objective lens 9, a first zoom lens group 18a, the first image forming lens 19a, first mirrors 20a and the first eyepiece 14a. First zoom lens group 18a, the first group lens 181a, a second group lens 182a, composed of the third lens group 183a and the fourth group lens 184a provided on the first upper optical axis _{L 1.} Among these, the first group lens 181a and the fourth group lens 184a are fixed to the lens frame 8 as fixed lenses. The second group lens 182a and the third group lens 183a are each provided as a moving lens so as to be movable along the _first optical axis L1.

The second optical axis _{L 2} are fixed objective lens 9, the second zoom lens group 18b, the second image forming lens 19b, the second folding mirror 20b and the second ocular lens 14b. Second zoom lens group 18b, the first lens group 181b, the second lens group 182b, comprised of the third group lens 183b and the fourth lens group 184b provided in the second on an optical axis _{L 2.} Among these, the first group lens 181b and the fourth group lens 184b are fixed to the body frame 8 as fixed lenses. The second group lens 182b and the third group lens 183b are each provided as a moving lens so as to be movable along the _second optical axis L2.

A second group lens 182a and the third group lens 183a and the second lens 182b and the third lens group 183b, the first on the optical axis _{L 1,} respectively, to move along the second upper optical axis _{L 2} Accordingly, the magnification of each observation image observed by the first and second eyepieces 14a and 14b is changed.

  The first and second folding mirrors 20a and 20b are provided in the lens barrel 11, respectively. The first and second folding mirrors 20 a and 20 b are provided on the folding shaft 21. As shown in FIG. 1, the folding shaft 21 is provided so as to be rotatable in the directions of arrows ab (clockwise direction a and counterclockwise direction b). For example, an operation knob 22 is provided at the right end of the folding shaft 21 as shown in FIG. This operation knob 22 is selectively operated to rotate the observation light from the sample 2 to either the first and second eyepieces 14a, 14b or the first and second TV cameras 15a, 15b. It is made to enter.

The sample 2 is epi-illuminated by an epi-illumination device (not shown) provided outside the stereomicroscope 1. The observation light from the sample 2 passes through the fixed objective lens 9, and further enters the first imaging lens 19a through the first zoom lens group 18a on the _first optical axis L1, and the first return. It is folded by the mirror 20a and enters the first eyepiece 14a.

At the same time, the observation light from the sample 2 enters the second imaging lens 19b through the second zoom lens group 18b on the _second optical axis L2, and is folded back by the second folding mirror 20b. The light enters the second eyepiece 14b. Thereby, each observation image is obtained through the first and second eyepieces 14a and 14b.

In this state, when the operation knob 22 is rotated in the direction of arrow a (clockwise), the first and second folding mirrors 20a and 20b are centered on the folding shaft 21 in response to the rotation of the folding shaft 21. 1 and retracts from the first optical axis L ₁ and the second optical axis L ₂ as indicated by dotted lines in FIG. Thereby, each observation light from the _first optical axis L ₁ and the second optical axis L ₂ travels straight and enters the first and second TV cameras 15 a and 15 b, and the first and second imaging are performed. Each observation image is formed on the elements 17a and 17b.

When the operation knob 22 is rotated in the direction of arrow b (counterclockwise), the first and second folding mirrors 20a and 20b rotate about the folding shaft 21 and again the first optical axis L ₁ , It arranged in the second on an optical axis L _2, first and second eyepiece lens 14a, the observation image through 14b is obtained.

  Even if the binocular tube does not have the dedicated first and second TV camera ports 16a and 16b, the first and second TV cameras 15a and 15b are used instead of the first and second eyepieces 14a and 14b. If left and right, the left and right observation images can be taken by the first and second TV cameras 15a and 15b as described above.

  As shown in FIG. 3, the first group lens 181a and the fourth group lens 184a are fixed to the lens frame 8 as described above. On the other hand, the second group lens 182a, which is a moving lens, is assembled and held in the second group lens frame 23a, and the third group lens 183a is assembled and held in the third group lens frame 24a. The first group lens 181b and the fourth group lens 184b are fixed to the lens frame 8 as described above. On the other hand, the second group lens 182b, which is a moving lens, is assembled and held in the second group lens frame 23b, and the third group lens 183b is assembled and held in the third group lens frame 24b.

  Each of the second group lens frame 23a, the third group lens frame 24a, the second group lens frame 23b, and the third group lens frame 24b is provided with grooves 25a and 25b on one side surface as shown in FIG. Yes. In addition, each groove | channel 25a, 25b shown in FIG. 4 is provided in the 3rd group lens frame 24a and the 3rd group lens frame 24b, respectively, and was provided in the 2nd group lens frame 23a and the 2nd group lens frame 23b. Each groove is not shown in the relationship of illustration.

As shown in FIGS. 3 and 4, the first guide shaft 26 a and the second guide shaft are parallel to the first optical axis L ₁ and the second optical axis L _{2 in} the lens frame 8. 26b is provided. Among these, each groove 25a provided in the second group lens frame 23a and the third group lens frame 24a is slidably fitted to the first guide shaft 26a. Each groove 25b provided in the second group lens frame 23b and the third group lens frame 24b is slidably fitted to the second guide shaft 26b.

Thus, the first optical axis L ₁ and on the second lens frame 23a and a third lens frame 24a along the first guide shaft 26a slide without play, and a second optical axis L ₂ above The second group lens frame 23b and the third group lens frame 24b slide along the second guide shaft 26b without backlash.

  As shown in FIG. 4, the second group lens frame 23a and the third group lens frame 24a are provided with respective sliding holes 27a, respectively, and the second group lens frame 23b and the third group lens frame 24b are also respectively provided. A sliding hole 27b is provided. The sliding holes 27a and 27b are provided in the third group lens frame 24a and the third group lens frame 24b, and are provided in the second group lens frame 23a and the second group lens frame 23b. The holes are not shown for the sake of illustration.

  As shown in FIG. 3, as a first moving mechanism, a first cylindrical cam 28a is fitted in each sliding hole 27a provided in the second group lens frame 23a and the third group lens frame 24a. On the side surface of the first cylindrical cam 28a, spiral cam grooves 29a and 30a are provided at the upper part and the lower part, respectively. The first cylindrical cam 28a is rotatably provided by the support members 31a and 32a at the upper part and the lower part, respectively.

  Guide pins 33a are provided on the second group lens frame 23a. The guide pin 33a is fitted in the cam groove 29a. The third group lens frame 24a is also provided with guide pins 34a. The guide pin 34a is fitted in the cam groove 30a.

  On the other hand, as shown in FIG. 3, a second cylindrical cam 28b as a second moving mechanism is fitted in each sliding hole 27b provided in the second group lens frame 23b and the third group lens frame 24b. On the side surface of the second cylindrical cam 28b, spiral cam grooves 29b and 30b are provided at the upper part and the lower part, respectively. The second cylindrical cam 28b is rotatably provided by the support members 31b and 32b in the upper part and the lower part, respectively.

  The cam grooves 29a, 30a of the first cylindrical cam 28a and the cam grooves 29b, 30b of the second cylindrical cam 28b are symmetrical about the center line Q and are provided in directions opposite to each other. .

  Guide pins 33b are provided on the second group lens frame 23b. The guide pin 33b is fitted in the cam groove 29b. The third group lens frame 24b is also provided with guide pins 34b. The guide pin 34b is fitted in the cam groove 30b.

  As shown in FIG. 3, a first transmission mechanism is provided on the upper portion of the first cylindrical cam 28a. That is, a spur gear 35a is assembled to the upper part of the first cylindrical cam 28a. A spur gear 36a is engaged with the spur gear 35a. The spur gear 36a is provided on the first transmission shaft 37a. A bevel gear 38a is provided coaxially with the spur gear 36a at the lower portion of the first transmission shaft 37a. The first transmission shaft 37a is rotatably provided. A bevel gear 39a is engaged with the bevel gear 38a. The bevel gear 39a is assembled to a first zoom handle shaft (first handle shaft) 40a.

  A second transmission mechanism is provided on the upper portion of the second cylindrical cam 28b. That is, a spur gear 35b is assembled to the upper part of the second cylindrical cam 28b. A spur gear 36b is engaged with the spur gear 35b. The spur gear 36b is provided on the second transmission shaft 37b. A bevel gear 38b is provided coaxially with the spur gear 36b below the second transmission shaft 37b. The second transmission shaft 37b is rotatably provided. A bevel gear 39b meshes with the bevel gear 38b. The bevel gear 39b is assembled to a second zoom handle shaft (second handle shaft) 40b.

  The first zoom handle shaft 40 a is rotatably held by a slide hole 41 a provided in the lens frame 8. A first washer 43a and a first rotation restricting member 44a are assembled and fixed to the first zoom handle shaft 40a on the shaft with the wall 42a of the lens frame 8 interposed therebetween. The first washer 43a and the first rotation restricting member 44a rotate integrally with the first zoom handle shaft 40a while being in contact with the wall 42a of the lens frame 8, and the shaft of the first zoom handle shaft 40a. Restrict movement in the direction.

  The first rotation restricting member 44a restricts the rotation range of the first zoom handle shaft 40a by the first restricting pin 45a provided on the lens frame 8 as shown in FIGS. A first zoom handle (first handle) 46a is attached to the first zoom handle shaft 40a on the first rotation regulating member 44a side.

  The second zoom handle shaft 40 b is rotatably held by a sliding hole 41 b provided in the lens frame 8. A second washer 43b and a second rotation restricting member 44b are assembled and fixed to the first zoom handle shaft 40b on the shaft with the wall 42b of the lens frame 8 interposed therebetween. Similarly to the above, the second washer 43b and the second rotation restricting member 44b rotate integrally with the second zoom handle shaft 40b while being in contact with the wall 42b of the lens frame 8, and the second zoom handle. The movement of the shaft 40b in the axial direction is restricted.

  The second rotation restricting member 44b restricts the rotation range of the second zoom handle shaft 40b by the second restricting pin 45b provided on the lens frame 8 in the same manner as shown in FIGS. . A second zoom handle (second handle) 46b is attached to the second rotation control member 44b side of the second zoom handle shaft 40b.

  On the outer peripheral surfaces of the first and second zoom handles 46a and 46b, indices indicating magnification, for example, indices "1x", "2x", "1x", "2x", "9x", respectively. ... "9x" is engraved. Further, a magnification reading instruction code “−” is engraved on each of the side surfaces 47 a and 47 b of the lens body frame 8. The indices “1 ×”, “2 ×”... “9 ×” are engraved with a symbol “−” for reading that the magnification reading instruction code “−” matches.

  Therefore, when the first and second zoom handles 46a and 46b are rotated, the indices “1 × −”, “2 × −”... Or “9 × −” that match the magnification reading instruction code “−” are read. Thus, the setting state of the magnification can be read.

  The first and second zoom handles 46a and 46b are opposed to each other. Among these, a connecting / releasing mechanism for connecting or releasing the first zoom handle shaft 40a and the second zoom handle shaft 40b is provided at the tip of the first zoom handle 46a. That is, the connecting member 48 is assembled and fixed to the distal end portion of the first zoom handle 46a. The connecting member 48 is provided with a sliding hole 49 at a portion facing the second zoom handle 46b. In the sliding hole 49, the tip end portion of the second zoom handle 46b is rotatably fitted.

  A stop member 50 as a restricting member is screwed onto the side surface of the connecting member 48. The stopper member 50 is penetrated from the side surface of the connecting member 48 into the sliding hole 49. The stop member 50 is screwed into the connecting member 48 or loosened by a tool 51 such as a driver. The stop member 50 is, for example, a screw member.

  When the stop member 50 is screwed in, the distal end portion of the stop member 50 comes into contact with the side surface 52 of the second zoom handle shaft 40b fitted in the slide hole 49 and is tightened. The second zoom handle shaft 40b is fixed in the sliding hole 49 by the pressing force of the stop member 50 against the side surface 52 of the second zoom handle shaft 40b. Thereby, the rotation of the second zoom handle shaft 40b is restricted in the sliding hole 49, and the rotation of the second zoom handle shaft 40b alone is restricted by the restriction of the rotation.

  The stop member 50 that is screwed into the connecting member 48 is positioned in the same direction as the horizontal direction in a state in which the rotation position of the first zoom handle shaft 40a is set, for example, at a position that indicates the minimum magnification as shown in FIG. It is suitable. That is, as shown in FIG. 5, the screwing direction of the stopper member 50 to the connecting member 48 is the same as the horizontal direction and faces the front cover 51 provided on the front side of the stereomicroscope main body. The front cover 53 is provided with an opening 54 as a hole, and a portion of the connecting member 48 where the stopper member 50 is screwed is opposed to the opening 54.

  In this state, the tool 51 can be fitted into the stop member 50 through the opening 54, and the stop member 50 can be tightened or loosened.

  As shown in FIG. 5, a closing member 55 formed of an elastic member, resin, or the like can be attached to and detached from the opening 54. The blocking member 55 blocks the opening 54 except during the screwing operation of the stop member 50 in order to prevent stray light from entering and to ensure airtightness.

  Next, observation of the sample 2 with the stereomicroscope configured as described above will be described.

  As shown in FIG. 4, the stop member 50 presses the side surface 52 of the second zoom handle shaft 40 b in the connecting member 48. Thereby, the second zoom handle shaft 40b is fixed by the connecting member 48, and the rotation of the connecting member 48 in the sliding hole 49 is restricted. In this state, the first zoom handle shaft 40a and the second zoom handle shaft 40b are in a state of rotating integrally.

  Each index “1 ×” “2 ×”... “9 ×” indicating each magnification carved on the outer peripheral surfaces of the first and second zoom handles 46a, 46b is the lowest magnification, for example, the magnification “1 ×”. If the index “1 ×” is set to match the magnification reading instruction code “−”, as shown in FIG. 6, the first zoom restricting member 44a is the first zoom restricting member 44a. It rotates in the direction of the arrow g until it comes into contact with the first restriction pin 45a, and its rotation is restricted when it comes into contact with the first restriction pin 45a. Similarly, the second zoom handle shaft 40b rotates integrally with the second zoom handle shaft 40b via the connecting member 48, so that the second rotation restricting member 44b contacts the second restricting pin 45b. It rotates in the direction of the arrow g until it comes into contact, and its rotation is restricted when it contacts the second restriction pin 45b.

  In this way, when the minimum magnification is set to “1 ×”, the second group lens 182a, the third group lens 183a, the second group lens 182b, and the third group lens 183b on the left and right sides as the moving lens are They are arranged at the respective positions shown in FIG. 2 and FIG.

In such a state, for example, when the first zoom handle 46a on the right side is rotated in the direction of arrow g (clockwise) shown in FIG. 6, the second zoom handle is responsive to the rotation of the first zoom handle 46a. The shaft 40b also rotates in the same arrow g direction. The bevel gear 39a is rotated by the rotation of the first zoom knob shaft 40a, the rotation of the bevel gear 39a is transmitted to the bevel gear 38a, whereby the first transmission shaft 37a shown in FIG. 4 is an arrow d ₁ direction Rotate. When the first transmission shaft 37a rotates, this rotation is transmitted from the spur gear 36a provided on the outer periphery of the first transmission shaft 37a to the first cylindrical cam 28a via the spur gear 35a. Thus, a first cylindrical cam 28a is rotated in the arrow e ₁ direction shown in FIG. 4 (the drawing clockwise).

At the same time, since the second zoom handle shaft 40b rotates integrally with the first zoom handle shaft 40a via the connecting member 48, the rotation of the second zoom handle shaft 40b causes the bevel gear 39b to rotate, the rotation of the bevel gear 39b is transmitted to the bevel gear 38b, whereby the second transmission shaft 37b as shown in FIG. 4 is rotated in the arrow c ₂ direction. When the second transmission shaft 37b rotates, this rotation is transmitted from the spur gear 36b provided on the outer periphery of the second transmission shaft 37b to the second cylindrical cam 28b via the spur gear 35b. Accordingly, the second cylindrical cam 28b is rotated in the direction of arrow f ₂ shown in FIG. 4 (drawings dihedral clockwise).

  Since the respective bevel gears 38a, 39a, 38b, 39b and the respective spur gears 35a, 36a, 35b, 36b are the same on the left and right, the first zoom handle 46a or the second zoom handle 46b is rotated with respect to the first zoom handle 46b. The rotational amounts of the cylindrical cam 28a and the second cylindrical cam 28b are also the same on the left and right.

Further, even if the second zoom handle shaft 40b instead of the first zoom handle 46a is rotated in the direction of the arrow g shown in FIG. 6 (clockwise direction), the first zoom handle 46b responds to the rotation of the first zoom handle 46b. since also the zoom knob shaft 40a rotates in the same direction of arrow g in the same manner as described above, the first cylindrical cam 28a is rotated in the arrow e ₁ direction, second cylindrical cam 28b rotates in the direction of arrow f ₂ .

Here, in the second group lens frame 23a and the third group lens frame 24a, the first guide shaft 26a is slidably fitted in each groove 25a, and the first guide shaft 26a is slidably inserted in each slide hole 27a. Since the cylindrical cam 28a is fitted, the rotation is restricted and the first cam shaft 26a is movable only in the axial direction, that is, in the same direction as the _first optical axis L1.

Further, the guide pins 33a and 34a fixed to the second group lens frame 23a and the third group lens frame 24a are slidable in the cam grooves 29a and 30a provided in the first cylindrical cam 28a, respectively. Therefore, when the first cylindrical cam 28a rotates, the guide pins 33a and 34a slide along the spiral cam grooves 29a and 30a as the first cylindrical cam 28a rotates. Move. As a result, the second group lens frame 23a and the third group lens frame 24a move in the same direction as the _first optical axis L1.

On the other hand, in the second group lens frame 23b and the third group lens frame 24b, similarly, the second guide shaft 26b is slidably fitted in the grooves 25b, and the second guide shaft 26b is slidably inserted in the slide holes 27b. Since the cylindrical cam 28b is fitted, the rotation is restricted, and the cylindrical cam 28b is movable only in the axial direction of the second guide shaft 26b, that is, in the same direction as the _second optical axis L2.

Furthermore, the guide pins 33b and 34b fixed to the second group lens frame 23b and the third group lens frame 24b are slidable in the cam grooves 29b and 30b provided in the second cylindrical cam 28b, respectively. Therefore, when the second cylindrical cam 28b rotates, the guide pins 33b and 34b slide along the spiral cam grooves 29b and 30b when the second cylindrical cam 28b rotates. Move. Accordingly, the second group lens frame 23b and the third group lens frame 24b move in the same direction as the _second optical axis L2.

However, when the first cylindrical cam 28a is rotated in the arrow e ₁ direction, the second group lens frame 23a is moved upward following the cam groove 29a, the third lens frame 24a below following the cam groove 30a Move in the direction.

Although the second cylindrical cam 28b is rotated in the direction of arrow _{f 2,} each of the cam grooves 29b, 30b are the cam grooves 29a, since the provided 30a and opposite, second group lens frame 23b in the cam groove 29b The third lens group frame 24b moves downward along the cam groove 30b.

  The first and second cylindrical cams 28a, 28b differ only in the respective rotation directions by the cam grooves 29a, 30a, 29b, 30b, so that the second group lens frame 23a, the third group lens frame 24a, The movement amounts of the second group lens frame 23b and the third group lens frame 24b are the same on the left and right.

As a result, the second group lens 182a and a second lens 182b as shown in FIG. 8, first the optical axis L _1, respectively, in the upward direction with the same moving amount along the second upper optical axis L ₂ move, and the second group lens 183a and a second lens 183b, the first on the optical axis L ₁ respectively, moves downward by the same amount of movement along the second on an optical axis L _2. If each of the second group lens 182a and the second group lens 182b and the second group lens 183a and the second group lens 183b move as described above, the sample is observed by the first and second eyepieces 14a and 14b. Each magnification of 2 is always the same.

  Further, when the first zoom handle 46a is rotated in the arrow g direction, the first rotation restricting member 44a comes into contact with the first restricting pin 45a as shown in FIG. When the first rotation restricting member 44a contacts the first restricting pin 45a, the rotation of the first zoom handle 46a is restricted. Similarly, the second zoom handle shaft 40b rotates until the second rotation restricting member 44b comes into contact with the second restricting pin 45b, and the rotation of the second zoom handle shaft 40b is restricted when it comes into contact with the second restricting pin 45b. In this state, the maximum magnification “9 ×” is set.

Contrary to the above, when the first zoom handle 46a is rotated in the direction of the arrow h (counterclockwise) shown in FIG. 7, the second zoom handle shaft 40b responds to the rotation of the first zoom handle 46a. Also rotate in the same arrow h direction. The rotation of the first zoom handle shaft 40a is transmitted to the first transmission shaft 37a via the respective bevel gears 39a and 38a as described above. When the first transmission shaft 37a is rotated in the arrow c ₁ direction, this rotational force is transmitted to the first cylindrical cam 28a via the spur gears 36a, 35a, whereby the first cylindrical cam 28a in FIG. 4 rotates in the arrow f ₁ direction (dihedral clockwise) shown in.

At the same time, since the second zoom handle shaft 40b also rotates integrally with the first zoom handle shaft 40a via the connecting member 48, the rotational force of the second zoom handle shaft 40b is the same as that described above. is transmitted to the cylindrical cam 28b, a second cylindrical cam 28b is rotated in the arrow e ₂ direction shown in FIG. 4 (the drawing clockwise).

When the first cylindrical cam 28a rotates in this way, the guide pins 33a and 34a slide along the spiral cam grooves 29a and 30a as the first cylindrical cam 28a rotates. the second lens frame 23a moves downward in the first optical axis L ₁ and the same direction, the third lens frame 24a is moved upward by the first optical axis L ₁ and the same direction.

At the same time, as the second cylindrical cam 28b rotates, the guide pins 33b and 34b slide along the spiral cam grooves 29b and 30b, so that the second lens group frame 23b to move down in the optical axis L ₂ in the same direction, the third group lens frame 24b is moved upward by the second optical axis L ₂ in the same direction.

As a result, the second group lens 182a and a second lens 182b as shown in FIG. 2, the first on the optical axis L _1, respectively, in the downward direction by the same amount of movement along the second upper optical axis L ₂ move, and the third group lens 183a and a third lens group 183b, the first on the optical axis L ₁ respectively, moves upward with the same amount of movement along the second on an optical axis L _2.

  Then, when the first zoom handle 46a is rotated in the direction of the arrow h and the first rotation restricting member 44a comes into contact with the first restricting pin 45a again as shown in FIG. 6, the first zoom handle 46a. , And the minimum magnification is returned to “1 ×”.

  Next, a case where the sample 2 is observed at different magnifications through the first and second eyepieces 14a and 14b will be described.

  As shown in FIG. 5, the blocking member 55 attached to the opening 54 provided in the front cover 53 is removed. At this time, since the first zoom handle 46a is set to the minimum magnification “1 ×”, the position of the stop member 50 of the connecting member 48 is a position facing the opening 54.

  In this state, as shown in FIG. 4, the tool 51 is inserted straightly through the opening 54 toward the stop member 50 of the connecting member 48. When the tool 51 is fitted to the stop member 50 and rotated, the stop member 50 is loosened with respect to the connecting member 48. As a result, the pressing of the second zoom handle shaft 40b against the side surface 52 by the stop member 50 in the connecting member 48 is released, and the second zoom handle shaft 40b can rotate within the sliding hole 49 of the connecting member 48. It becomes a state. In this state, the first zoom handle shaft 40a and the second zoom handle shaft 40b are disconnected and rotate independently of each other.

  However, when the first zoom handle 46a is rotated in the direction of the arrow g shown in FIG. 6 (clockwise), the rotation of the first zoom handle 46a is caused by the first transmission shaft via the respective bevel gears 39a and 38a. It is transmitted only to 37a. That is, since the connection between the first zoom handle shaft 40a and the second zoom handle shaft 40b is released, the rotation of the first zoom handle shaft 40a is not transmitted to the second zoom handle shaft 40b.

When the first transmission shaft 37a is rotated in the arrow d ₁ direction, this rotational force is the spur gear 36a, it is transmitted to the first cylindrical cam 28a through 35a, whereby the first cylindrical cam 28a is in Figure 4 It rotates in the direction indicated by arrow e ₁ (clockwise in the drawing). As the first cylindrical cam 28a rotates, the guide pins 33a and 34a slide along the spiral cam grooves 29a and 30a, so that the second lens group frame 23a is moved to the first optical axis L. ₁ and the third lens group frame 24a moves downward in the same direction as the _first optical axis L1.

As a result, the second group lens 182a moves upward along the _first optical axis L1, and the third group lens 183a moves downward along the _first optical axis L1. Therefore, only the magnification of the image of the sample 2 observed through one eyepiece 14a can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

  On the other hand, when the second zoom handle 46b is rotated, the rotation of the second zoom handle 46b is transmitted only to the second transmission shaft 37b via the respective bevel gears 39b and 38b. That is, since the connection between the second zoom handle shaft 40b and the first zoom handle shaft 40a is released, the rotation of the second zoom handle shaft 40b is not transmitted to the first zoom handle shaft 40a.

When the second transmission shaft 37b rotates, this rotational force is transmitted to the second cylindrical cam 28b via the spur gears 36b and 35b, whereby the second cylindrical cam 28b rotates. As the second cylindrical cam 28b rotates, the guide pins 33b and 34b slide along the spiral cam grooves 29b and 30b, so that the second lens group frame 23b is moved to the second optical axis L. moving upward on the _2, the third group lens frame 24b is moved downward on the second optical axis L _2.

As a result, the second group lens 182b moves, for example, upward along the _second optical axis L2, and the third group lens 183b moves, for example, downward along the _second optical axis L2. To do. Accordingly, only the magnification of the image of the sample 2 observed through the other eyepiece 14b can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

Thus the first and the second group lens 182a, and the third group lens 183a on the optical axis _{L 1,} the second optical axis _L and ₂ on the second lens 182b and the third group lens 183b are each independently For example, as shown in FIG. 9, the maximum magnification “9 times” is set by rotating the first zoom handle 46a, and the minimum magnification “1 time” is set by rotating the second zoom handle 46b. Is possible.

  When reconnecting the first zoom handle shaft 40a and the second zoom handle shaft 40b, the first zoom handle 46a is set to the lowest magnification “1 ×” and the second zoom handle 46b is set to the lowest. Set the magnification to “1 ×”. By setting the first zoom handle 46a to the minimum magnification “1 ×”, the position of the stop member 50 of the connecting member 48 is opposed to the opening 54 as shown in FIG.

  In this state, the closing member 55 attached to the opening 54 provided in the front cover 53 is removed, and the tool 51 advances straight through the opening 54 toward the stop member 50 of the connecting member 48 as shown in FIG. Plug in. When the tool 51 is rotated while being fitted to the stopper member 50, the stopper member 50 is tightened with respect to the connecting member 48. By tightening the stop member 50, the stop member 50 presses the side surface 52 of the second zoom handle shaft 40 b to fix the second zoom handle shaft 40 b in the sliding hole 49 of the connection member 48. . As a result, the first zoom handle shaft 40a and the second zoom handle shaft 40b are connected to each other and rotate together again.

  When the first zoom handle shaft 40a and the second zoom handle shaft 40b are connected and released, the first zoom handle 46a and the second zoom handle 46b are set to the minimum magnification “1 ×”, that is, FIG. As shown in FIG. 6, the first rotation restricting members 44a and 44b come into contact with the first and second restricting pins 45a and 45b to restrict the rotations of the first and second zoom handle shafts 40a and 40b, respectively. It is done in the state.

  Thus, the first zoom handle shaft 40a and the second zoom handle shaft 40b are in a state equivalent to a state in which the first zoom handle shaft 40a and the second zoom handle shaft 40b are positioned in contact with each other. Since the first zoom handle shaft 40a and the second zoom handle shaft 40b are connected to and released from each other, even if the first zoom handle shaft 40a and the second zoom handle shaft 40b are reconnected, these The rotational positions of the first zoom handle shaft 40a and the second zoom handle shaft 40b do not change from the state before the connection is released.

  Therefore, even if the first zoom handle shaft 40a and the second zoom handle shaft 40b are reconnected, the state before the connection is released is reproduced, so that the first and second eyepieces 14a, 14b after the reconnection are reproduced. The magnifications are always the same.

  As described above, according to the first embodiment, the first zoom handle shaft 40a and the second zoom handle shaft 40b are connected or released by tightening and loosening the stop member 50 of the connecting member 48. In addition, in response to each rotation of the first zoom handle shaft 40a and the second zoom handle shaft 40b, the second group lens 182a and the third group lens 183a, the second group lens 182b and the third group lens 183b, Are linked or independently moved up and down, so that even a stereomicroscope originally intended for stereoscopic observation of the sample 2 is observed through the first and second eyepieces 14a and 14b. Each magnification of the sample 2 can be set to a different magnification at the same time.

  Since the first zoom handle shaft 40a and the second zoom handle shaft 40b can be connected or released by tightening and loosening the connecting member 48 by the stopper member 50, the first zoom handle shaft 40a and the second zoom handle shaft 40b can be connected to or released from the original function of the stereomicroscope. Stereoscopic observation and observation of the sample 2 at different magnifications in the left and right eyepieces 14a and 14b can be selected. Stereo microscopes can be used for a wide range of applications by selecting these observations.

  As a result, when different magnifications are set in the first and second eyepieces 14a and 14b as shown in FIG. 9, for example, if the TV cameras 15a and 15b are respectively attached to the two TV camera ports 16a and 16b, The same sample 2 can be simultaneously imaged at different magnifications, and the images captured by the TV cameras 15 a and 15 b can be simultaneously displayed on the monitor 77 via the PC 76. In addition to the PC 76 and the monitor 77 shown in the figure, if two TV monitors (not shown) are attached to the TV cameras 16a and 16b, images taken at different magnifications of the sample 2 can be simultaneously displayed on the TV monitor. .

  Therefore, for example, when inspecting the appearance of the whole part and the details of the part in the production factory, the inspection can be completed at low and high times at the same time the part is placed on the stage, and the inspection efficiency can be improved. . In addition, it is possible to easily meet the demands of the medical / research field in which one sample 2, for example, the shape and color of a biological specimen, is to be observed through a TV camera in real time at two different magnifications.

  Since the first zoom handle shaft 40a and the second zoom handle shaft 40b can be connected and released only by screwing the stop member 50, the operation is easy. In addition, the first zoom handle shaft 40a and the second zoom handle shaft 40b are connected to and disconnected from each other in a state where the first zoom handle 46a and the second zoom handle 46b are set to the minimum magnification “1 ×”. Therefore, even if the first zoom handle shaft 40a and the second zoom handle shaft 40b are reconnected, the state before connection can be reproduced, and the first and second eyepieces 14a and 14b after reconnection can be reproduced. Each magnification must be the same.

  The first embodiment may be modified as follows. For example, the moving mechanisms of the second group lens 182a and the third group lens 183a, which are moving lenses, and the second group lens 182b and the third group lens 183b use the first and second cylindrical cams 28a and 28b, respectively. For example, the zoom zoom mechanism using the plate cam described in Patent Document 1, that is, the zoom moving lenses arranged on the left and right are moved in the vertical direction by two plate cams provided on both sides of the zoom handle shaft. A mechanism for performing zooming may be used.

Further, not limited to be applied to the stereomicroscope Galilean, it is also applicable to the first optical axis L ₁ and the second Greenough type stereomicroscope optical axis L ₂ is inclined. This Greenough type stereomicroscope, for example, the first is inclined respective to the optical axis L ₁ of the second optical axis L ₂ and the respective guide shafts in parallel each provided, the second group lens frame 23b on the guide shaft This can be realized by movably providing the third group lens frame 24b. The first zoom handle shaft 40a and the second zoom handle shaft 40b are connected and released by the connecting member 48.

  In the structure in which the second zoom handle shaft 40b is fixed or released by the stop member 50 in the connecting member 48, for example, as shown in FIG. 10, a connecting groove 56 is provided at the tip of the second zoom handle shaft 40b. The stop member 50 may be applied to the connecting groove 56. Needless to say, the stopper member 50 is applied to the connecting groove 56 in the sliding hole 49 of the connecting member 48.

  Further, in the structure for connecting or releasing the second zoom handle shaft 40b, as shown in FIG. 11, a connection hole 58 having a flat contact surface 57 is provided on the second zoom handle shaft 40b, and this connection is made. The stopper member 50 may be fixed in surface contact with the contact surface 57 of the hole 57.

  The connecting member 48 is provided at the distal end portion of the first zoom handle shaft 40a, but is provided at the distal end portion of the second zoom handle shaft 40b, and the first zoom handle shaft 40a is inserted into the sliding hole 49 of the connecting member 48. May be fitted.

  Next, a second embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 9 are denoted by the same reference numerals, and detailed description thereof is omitted.

  12 is a cross-sectional view taken along the line BB in FIG. 3 showing the configuration of the zoom lens body of the Galileo stereomicroscope. A first zoom handle shaft 40a is assembled to the first zoom handle 46a. The first zoom handle shaft 60a is rotatably held by the slide holes 41a and 41b provided in the lens frame 8, and has a washer 43a and a washer 43a on the shaft across the wall 42a of the lens frame 8. A rotation restricting member 44a is assembled and fixed.

  The first zoom handle shaft 60a is formed in a cylindrical shape having a hollow portion 61 between a tip portion thereof and a portion where the first zoom handle 46a is provided. Further, on the side of the first zoom handle shaft 60a where the first zoom handle 46a is provided, between the wall 42a of the lens frame 8 and the first zoom handle 46a, the first zoom handle shaft 60a and A connecting member 62 is provided that constitutes a connection / release mechanism that connects or releases the second zoom handle shaft 60b.

  The connecting member 62 has an outer diameter larger than the outer diameter of the first zoom handle shaft 60a, and is formed in a columnar shape, for example. The outer diameter of the connecting member 62 is smaller than the outer diameter of the first zoom handle 46a. A stop member 63 is screwed onto the side surface of the connecting member 62. The stop member 63 is inserted from the side surface of the connecting member 62 into the hollow portion 61.

  The stop member 63 is screwed into the connecting member 62 or loosened by a tool 51 such as a screwdriver. When the stop member 63 is screwed in, the distal end portion of the stop member 63 comes into contact with the side surface 64 of the second zoom handle shaft 60b fitted in the hollow portion 61 and is second tightened. The second zoom handle shaft 60b is fixed in the hollow portion 61 by the pressing force of the stop member 63 against the side surface 64 of the zoom handle shaft 60b. Thereby, the rotation of the second zoom handle shaft 60b is restricted in the hollow portion 61, and the rotation of the second zoom handle shaft 60b alone is restricted by the restriction of the rotation.

  The position of the stop member 63 screwed to the connecting member 62 is the same as the horizontal direction in a state where, for example, the rotation position of the first zoom handle shaft 60a is set to a position showing the minimum magnification, as shown in FIG. They are oriented in the same direction. That is, the screwing direction of the stopper member 63 to the connecting member 62 is the same as the horizontal direction. In this state, the tool 51 can be fitted into the stop member 63, and the stop member 63 can be tightened or loosened.

  When the first zoom handle shaft 60a and the second zoom handle shaft 60b are reconnected, the first zoom handle 46a is set to the minimum magnification “1 ×” as described above, and the second zoom handle is used. 46b is not limited to the minimum magnification “1 ×” but can be set to different magnifications. This is because the stop member 63 of the connecting member 62 into which the tool 51 is inserted is provided outside the lens frame 8. For example, the first zoom handle 46a can be set to a magnification “9 ×”, and the second zoom handle 46b can be set to a magnification “2 ×”.

  The second zoom handle shaft 60b is rotatably inserted into the hollow portion 61 of the first zoom handle shaft 60a. Accordingly, the outer diameter of the portion of the second zoom handle shaft 60b inserted into the hollow portion 61 of the first zoom handle shaft 60a is slightly smaller than the inner diameter of the hollow portion 61 of the first zoom handle shaft 60a. Has been.

  Next, a case where the sample 2 is observed at different magnifications through the left and right eyepieces 14a and 14b will be described.

  Since the first zoom handle 46a is in the state set to the minimum magnification “1 ×”, the position of the stop member 63 of the connecting member 62 is oriented in the same direction as the horizontal direction.

  In this state, the tool 51 is inserted into the stop member 63 of the connecting member 62. When the tool 51 is fitted to the stop member 63 and rotated, the stop member 63 is loosened with respect to the connecting member 62. As a result, the pressing of the second zoom handle shaft 60b against the side surface 64 by the stop member 63 in the connecting member 62 is released, and the second zoom handle shaft 60b is rotatable in the hollow portion 61 of the connecting member 62. become. In this state, the first zoom handle shaft 60a and the second zoom handle shaft 60b are disconnected and rotate independently of each other.

However, when the first zoom handle 46a is rotated in the direction of the arrow g shown in FIG. 6 (clockwise), the rotation of the first zoom handle 46a is similar to that described above via the bevel gears 39a and 38a. Is transmitted only to one transmission shaft 37a, and further transmitted to the first cylindrical cam 28a via the spur gears 36a and 35a. As a result, the first cylindrical cam 28a rotates, and accordingly, the guide pins 33a and 34a slide along the spiral cam grooves 29a and 30a, and the second group lens frame 23a moves to the first. moving upward on the optical axis L _1, the third group lens frame 24a is moved downward by the first on the optical axis L _1.

As a result, the second group lens 182a moves upward along the _first optical axis L1, and the second group lens 183a moves downward along the _first optical axis L1. Accordingly, only the magnification of the image of the sample 2 observed through the first eyepiece 14a can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

On the other hand, when the second zoom handle 46b is rotated, the rotation of the second zoom handle 46b is transmitted only to the second transmission shaft 37b via the respective bevel gears 39b, 38b, and further, each spur gear 36b, It is transmitted to the second cylindrical cam 28b via 35b. As a result, the second cylindrical cam 28b rotates, and accordingly, the guide pins 33b and 34b slide along the spiral cam grooves 29b and 30b, and the second group lens frame 23b becomes the second lens frame 23b. moving upward example on the optical axis L _2, the third group lens frame 24b is moved downward on the second optical axis L _2.

As a result, when the second group lens 182b moves, for example, upward along the _second optical axis L2, the third group lens 183b moves downward along the _second optical axis L2. Therefore, only the magnification of the image of the sample 2 observed through the second eyepiece 14b can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

  When reconnecting the first zoom handle shaft 60a and the second zoom handle shaft 60b, the first zoom handle 46a is set to the lowest magnification “1 ×” and the second zoom handle 46b is set to the lowest. Set the magnification to “1 ×”.

  In this state, when the tool 51 is inserted into the stop member 63 of the connecting member 62 and rotated, the stop member 63 is tightened against the connecting member 62. Accordingly, the stop member 63 presses the side surface 64 of the second zoom handle shaft 60b, and the second zoom handle shaft 60b is fixed by the hollow portion 61 of the connecting member 62. As a result, the first zoom handle shaft 60a and the second zoom handle shaft 60b are connected to each other and rotate together again.

  Even if the first zoom handle shaft 60a and the second zoom handle shaft 60b are reconnected, the state before the connection is released is reproduced. Therefore, each of the first and second eyepieces 14a and 14b after the reconnection is reproduced. The magnification must be the same.

  When the first zoom handle shaft 60a and the second zoom handle shaft 60b are reconnected, different magnifications can be set. For example, the first zoom handle 46a is set to the magnification “9 ×”, and the second zoom handle 46b is set to the magnification “2 ×”.

  If the first zoom handle shaft 60a and the second zoom handle shaft 60b are reconnected in this state, the magnification of the image of the sample 2 observed through the first eyepiece 14a and the observation through the second eyepiece 14b are observed. The magnification of the image of the sample 2 to be changed is interlocked and varied while maintaining different states.

  As described above, according to the second embodiment, the connecting member 62 is formed on the first zoom handle shaft 60a having the hollow portion 61, and the connecting member 62 is connected to the wall 42a of the lens frame 8 and the first zoom member shaft 60a. The first zoom handle shaft 60a and the second zoom handle shaft 60b are connected and released by screwing or loosening the stop member 63 in the connecting member 62, provided between the zoom handle 46a. Therefore, the same effect as in the first embodiment, that is, even a stereomicroscope that is originally premised on stereoscopic observation of the sample 2 is observed through the left and right eyepieces 14a and 14b. Each magnification of the sample 2 can be set to a different magnification at the same time.

  Further, the connection member 62 is connected to the lens frame in an operation different from the effect of the first embodiment, that is, the operation of connecting and releasing the first zoom handle shaft 60a and the second zoom handle shaft 60b. 8, it is not necessary to attach and detach the closing member 55 as in the first embodiment, and the workability is excellent. At the same time, the lens frame 8 does not need to be provided with the opening 54 for attaching and detaching the closing member 55, so that the airtightness of the lens frame 8 can be increased.

  Further, the first zoom handle shaft 60a and the second zoom handle shaft 60b can be connected in a state where the first zoom handle shaft 60a and the second zoom handle shaft 60b are set to different magnifications. Thus, the magnification of the image of the sample 2 observed through the first eyepiece lens 14a and the magnification of the image of the sample 2 observed through the second eyepiece lens 14b can be interlocked and varied while being different from each other. In addition, a plurality of magnifications can be set quickly.

  The second embodiment can also be applied to a Greenough-type stereomicroscope, as in the first embodiment.

  Needless to say, the structure shown in FIG. 10 or FIG. 11 may be used as the structure for connecting or releasing the second zoom handle shaft 60b with the stop member 63 in the connecting member 62, for example.

  Further, a hollow portion is provided in the second zoom handle shaft 60b, a connecting member 62 is formed on the second zoom handle shaft 60b, and the stop member 63 is screwed or loosened in the connecting member 62 to thereby form the first. The zoom handle shaft 60a and the second zoom handle shaft 60b may be connected and released.

  Next, a third embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIGS. 1 to 9 are denoted by the same reference numerals, and detailed description thereof is omitted.

  FIG. 13 is a cross-sectional view taken along the line BB in FIG. 3 showing the configuration of the zoom lens body of the Galileo stereo microscope. A first zoom handle 71a as a connecting member is assembled to the first zoom handle shaft 70a. The first zoom handle shaft 70 a is formed in a cylindrical shape having a hollow portion 72. A sliding hole 73 is provided in the first zoom handle 71a. The hollow portion 72 and the sliding hole 73 are coaxially connected. The first zoom handle shaft 70a is rotatably held by the slide holes 41a and 41b provided in the lens frame 8, and has a washer 43a and a washer 43a on the shaft across the wall 42a of the lens frame 8. A rotation restricting member 44a is assembled and fixed.

  The second zoom handle shaft 70b is rotatably inserted into the hollow portion 72 of the first zoom handle shaft 70a. Accordingly, the outer diameter of the portion of the second zoom handle shaft 70b inserted into the hollow portion 72 of the first zoom handle shaft 70a is slightly smaller than the inner diameter of the hollow portion 72 of the first zoom handle shaft 70a. Has been.

  The distal end portion of the second zoom handle shaft 70b passes through the sliding hole 73 of the first zoom handle 71a and protrudes to the outside of the first zoom handle 71a. A second zoom handle 46c is assembled to the tip of the second zoom handle shaft 70b protruding from the first zoom handle 71a.

  The second zoom handle 46c is provided outside the first zoom handle 71a and has an outer diameter smaller than the outer diameter of the first zoom handle 71a. Accordingly, the second zoom handle 46b and the second zoom handle 46c are attached to both ends of the second zoom handle shaft 70b, respectively.

  A stop member 74 is screwed onto the side surface of the first zoom handle 71a as a connecting member. The stop member 74 is penetrated from the side surface of the first zoom handle 71 a to the inside of the sliding hole 73.

  The stop member 74 is screwed into the first zoom handle 71a or loosened by a tool 51 such as a driver. When the stop member 74 is tightened, the distal end portion of the stop member 74 comes into contact with the side surface 75 of the second zoom handle shaft 70b fitted in the slide hole 73, and the second zoom when the stop member 74 is tightened. The second zoom handle shaft 70b is fixed in the sliding hole 73 by the pressing force of the stop member 74 against the side surface 75 of the handle shaft 70b. Thereby, the rotation of the second zoom handle shaft 70b is restricted in the sliding hole 73, and the rotation of the second zoom handle shaft 70b alone is restricted by the restriction of the rotation.

  The stop member 74 that is screwed into the first zoom handle 71a is positioned horizontally, for example, with the rotational position of the first zoom handle 71a being set to a position that indicates the minimum magnification, for example, as shown in FIG. The direction is the same as the direction. That is, the screwing direction of the stopper member 74 to the first zoom handle 71a is the same as the horizontal direction. In this state, the operation of fitting the tool 51 into the stop member 74 and tightening or loosening the stop member 74 becomes easy.

  When the first zoom handle shaft 70a and the second zoom handle shaft 70b are reconnected, the first zoom handle 71a is set to the minimum magnification “1 ×” as described above, and the second zoom handle is used. 46b and 46c are not limited to the minimum magnification “1 ×” but can be set to different magnifications. This is because, like the second embodiment, the stop member 74 of the first zoom handle 71a into which the tool 51 is inserted is provided outside the lens frame 8.

  Next, a case where the sample 2 is observed at different magnifications through the first and second eyepieces 14a and 14b will be described.

  Since the first zoom handle 71a is set to the minimum magnification “1 ×”, the position of the stop member 74 of the first zoom handle 71a is in the same direction as the horizontal direction.

  In this state, when the tool 51 is inserted into the stop member 74 and the tool 51 is fitted to the stop member 74 and rotated, the stop member 74 is loosened with respect to the first zoom handle 71a. As a result, the pressing of the stopper member 74 against the side surface 75 of the second zoom handle shaft 70b in the first zoom handle 71a is released, and the second zoom handle shaft 70b is released from the hollow portion 72 of the first zoom handle 71a. It becomes possible to rotate within. In this state, the first zoom handle shaft 70a and the second zoom handle shaft 70b are disconnected and rotate independently of each other.

However, when the first zoom handle 71a is rotated in the direction of the arrow g shown in FIG. 6 (clockwise direction), the rotation of the first zoom handle 71a is similar to that described above via the bevel gears 39a and 38a. Is transmitted only to one transmission shaft 37a, and further transmitted to the first cylindrical cam 28a via the spur gears 36a and 35a. As a result, the first cylindrical cam 28a rotates, and accordingly, the guide pins 33a and 34a slide along the spiral cam grooves 29a and 30a, and the second group lens frame 23a moves to the first. moving upward on the optical axis L _1, the third group lens frame 24a is moved downward by the first on the optical axis L _1.

As a result, when the second group lens 182a moves upward along the _first optical axis L1, the second group lens 183a moves downward along the _first optical axis L1. Therefore, only the magnification of the image of the sample 2 observed through the first eyepiece 14a can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

On the other hand, when the second zoom handle 46b and / or 46c is rotated, the rotation of the second zoom handle 46b and / or 46c is transmitted only to the second transmission shaft 37b via the respective bevel gears 39b and 38b. Further, it is transmitted to the second cylindrical cam 28b via the spur gears 36b and 35b. As a result, the second cylindrical cam 28b rotates, and accordingly, the guide pins 33b and 34b slide along the spiral cam grooves 29b and 30b, and the second group lens frame 23b becomes the second lens frame 23b. moving upward example on the optical axis L _2, the third group lens frame 24b is moved downward on the second optical axis L _2.

As a result, when the second group lens 182b moves, for example, upward along the _second optical axis L2, the third group lens 183b moves downward along the _second optical axis L2. Therefore, only the magnification of the image of the sample 2 observed through the second eyepiece 14b can be arbitrarily set independently, for example, “1 ×”, “2 ×”, or “9 ×”.

  When the first zoom handle shaft 70a and the second zoom handle shaft 70b are reconnected, for example, the first zoom handle 71a is set to the minimum magnification “1 ×” and the second zoom handles 46b and 46c are used. Is also set to the minimum magnification “1 ×”.

  In this state, when the tool 51 is inserted into the stop member 74 of the first zoom handle 71a and rotated, the stop member 74 is tightened with respect to the first zoom handle 71a. Accordingly, the stop member 74 presses the side surface 75 of the second zoom handle shaft 70b, and fixes the second zoom handle shaft 70b within the hollow portion 72 of the second zoom handle shaft 70a. As a result, the first zoom handle shaft 70a and the second zoom handle shaft 70b are connected and rotate integrally.

  Even if the first zoom handle shaft 70a and the second zoom handle shaft 70b are reconnected, the state before the connection is released is reproduced. Therefore, each of the first and second eyepieces 14a and 14b after the reconnection is reproduced. The magnification must be the same.

  When reconnecting the first zoom handle shaft 70a and the second zoom handle shaft 70b, it is possible to set different magnifications. For example, the first zoom handle 71a is set to the magnification “9 ×”, and the second zoom handles 46b and 46c are set to the magnification “2 ×”.

  If the first zoom handle shaft 70a and the second zoom handle shaft 70b are reconnected in this state, the magnification of the image of the sample 2 observed through the first eyepiece 14a and the observation through the second eyepiece 14b are observed. The magnification of the image of the sample 2 to be changed is interlocked and varied while maintaining different states.

  As described above, according to the third embodiment, the second zoom handle shaft 70b passes through the first zoom handle shaft 70a having the hollow portion 72, and the first zoom handle shaft 70a has the first zoom handle shaft 70a. The zoom handle 71a is assembled and the first zoom handle shaft 70a is screwed or loosened to connect the first zoom handle shaft 70a and the second zoom handle shaft 70b and release them. As described above, the same effects as those of the first embodiment, that is, the first and second eyepieces 14a, 14a, Each magnification of the sample 2 observed through 14b can be set to a different magnification at the same time.

  Further, since the second zoom handle shaft 70b is assembled with the second zoom handles 46b and 46c for operation at both ends thereof, it is different from the effect of the first embodiment. Even if the second zoom handle 46b or 46c is operated, the second zoom handle shaft 70b can be rotated.

  The first zoom handle shaft 70a and the second zoom handle shaft 70b are connected to and released from the first zoom handle 71a because the first zoom handle 71a is provided outside the lens frame 8. It is not necessary to attach and detach the closing member 55 as in the embodiment, and the workability is excellent. At the same time, the lens frame 8 does not need to be provided with the opening 54 for attaching and detaching the closing member 55, so that the airtightness of the lens frame 8 can be increased.

  Furthermore, the first zoom handle shaft 70a and the second zoom handle shaft 70b can be connected with the first zoom handle shaft 70a and the second zoom handle shaft 70b set to different magnifications. Thereby, the magnification of the image of the sample 2 observed through the first eyepiece lens 14a and the magnification of the image of the sample 2 observed through the second eyepiece lens 14b are changed in conjunction with each other while being different from each other. Multiple magnifications can be set quickly.

  For example, the first zoom handle 71a and the second zoom handle 46c are provided to connect and release the first zoom handle shaft 70a and the second zoom handle shaft 70b as described above. It can be done with only one side operation, and it has excellent operability.

  The third embodiment can also be applied to a Greenough-type stereomicroscope, as in the first embodiment.

  Needless to say, the structure shown in FIG. 10 or FIG. 11 may be used as the structure for fixing or releasing the second zoom handle shaft 70b by the stop member 74 in the first zoom handle 71a. .

  In addition, the second zoom handle shaft 70b is not limited to pass through the hollow portion 72 of the first zoom handle shaft 70a, but a hollow portion is provided in the second zoom handle shaft 70b, and the first zoom handle shaft 70b is provided in the hollow portion. You may make it penetrate the handle shaft 70a.

  In the above-described embodiment, the first handle shaft and the second handle shaft are connected or released by the connection / release mechanism, but the present invention is not limited to this. In addition, the connection / release mechanism is configured to use a screw member, but is not limited thereto, and may be a mechanism using a clutch mechanism, for example.

  These mechanisms are not limited to a stereomicroscope, but can be applied to any optical apparatus having a plurality of independent variable magnification optical systems.

BRIEF DESCRIPTION OF THE DRAWINGS The block diagram which shows 1st Embodiment of the Galileo-type stereomicroscope based on this invention. The front view in a stereomicroscope. The block diagram of the zoom lens part in the same stereomicroscope. CC sectional drawing in the same stereoscopic microscope. BB sectional drawing in the same stereoscopic microscope. DD sectional drawing at the time of the minimum magnification in the same stereoscopic microscope. DD sectional view at the maximum magnification in the same stereomicroscope. The front view at the time of the same magnification and the maximum magnification in the same stereomicroscope. The front view at the time of the lowest magnification on the left side and the maximum magnification on the right side in the same stereomicroscope. The figure which shows the modification of the connection mechanism in the same stereoscopic microscope. The figure which shows the modification of the connection mechanism in the same stereoscopic microscope. The block diagram of the zoom lens body part which is 2nd Embodiment of the Galileo-type stereomicroscope based on this invention. The block diagram of the zoom lens body part which is 3rd Embodiment of the Galileo-type stereomicroscope based on this invention.

Explanation of symbols

  1: stereo microscope, 2: sample, 3: stage, 4: frame, 5: support arm, 6: focusing handle, 7: zoom lens, 8: lens frame, 9: fixed objective lens, 10: mounting part , 11: lens barrel, 12: mounting portion, 13a, 13b: lens, 14a: first eyepiece, 14b: second eyepiece, 15a: first television camera (TV camera), 15b: second Television camera (TV camera), 16a: first TV camera port, 16b: second TV camera port, 17a: first image sensor, 17b: second image sensor, 18a: first zoom lens Group, 19a: first imaging lens, 20a: first folding mirror, 181a: first group lens, 182a: second group lens, 183a: third group lens, 184a: fourth group lens, 18b: first 2 zoom lens 19b: second imaging lens, 20b: second folding mirror, 181b: first group lens, 182b: second group lens, 183b: third group lens, 184b: fourth group lens, 21: for folding Axis, 22: operation knob, 23a: second group lens frame, 24a: third group lens frame, 23b: second group lens frame, 24b: third group lens frame, 25a, 25b: groove, 26a: first Guide shaft, 26b: second guide shaft, 27a: sliding hole, 27b: sliding hole, 28a: first cylindrical cam, 29a, 30a: cam groove, 31a, 32a: support member, 33a: guide pin, 34a: guide pin, 28b: second cylindrical cam, 27b: sliding hole, 29b, 30b: cam groove, 31b, 32b: support member, 33b: guide pin, 34b: guide pin, 35a, 35b: spur gear, 36a, 36 : Spur gear, 37a: First transmission shaft, 37b: Second transmission shaft, 38a, 38b, 39a, 39b: Bevel gear, 40a: First zoom handle shaft, 40b: Second zoom handle shaft, 41a , 41b: sliding hole, 42a, 42b: wall of the lens frame, 43a: first washer, 43b: second washer, 44a: first rotation restricting member, 44b: second rotation restricting member, 45a : First restricting pin, 45b: second restricting pin, 46a: first zoom handle, 46b: second zoom handle, 47a, 47b: side surface of the lens frame, 48: connecting member, 49: sliding Hole: 50: Stopping member, 51: Tool, 52: Side surface of second zoom handle, 53: Front cover, 54: Opening part, 55: Closing member, 56: Groove for connection, 57: Contact surface, 58: Connecting hole, 60a: first zoom hand 61: hollow portion, 62: connecting member, 63: stop member, 60b: second zoom handle shaft, 64: side surface of the second zoom handle shaft, 70a: first zoom handle shaft, 71a: first 1 zoom handle, 72: hollow portion, 73: sliding hole, 70b: second zoom handle shaft, 46c: second zoom handle, 74: stop member, 75: side surface of the second zoom handle shaft, 76 : PC, 77: monitor.

Claims (17)

A first optical system having at least one lens movable in the first optical axis direction;
A second optical system having at least one lens movable in the second optical axis direction;
An interlocking switching mechanism for moving the first lens and the second lens in conjunction with each other and releasing the interlocking and independently moving;
A stereomicroscope characterized by comprising: The interlock switching mechanism is
A first moving mechanism for moving the first optical system on the first optical axis;
A second moving mechanism for moving the second optical system on the second optical axis;
The stereomicroscope according to claim 1, further comprising: The interlock switching mechanism includes a first transmission mechanism for operating the first moving mechanism;
A second transmission mechanism for operating the second moving mechanism;
A connection / release mechanism for connecting the first transmission mechanism and the second transmission mechanism or releasing the connection;
Interlocking or releasing the interlocking between the first moving mechanism and the second moving mechanism;
The stereomicroscope according to claim 2, wherein: In a stereomicroscope having first and second optical axes and stereoscopically viewing a sample through the first and second optical axes,
At least one first lens movably provided on the first optical axis;
At least one second lens movably provided on the second optical axis;
A first lens frame for holding the first lens;
A second lens frame for holding the second lens;
A first guide shaft for guiding the first lens frame in a direction along the first optical axis;
A second guide shaft for guiding the second lens frame in a direction along the second optical axis;
A first moving mechanism for moving the first lens frame along the first guide axis;
A second moving mechanism for moving the second lens frame along the first guide shaft;
A first handle for moving the first lens;
A second handle for moving the second lens;
A first handle shaft provided on the first handle;
A second handle shaft provided on the second handle;
A first transmission mechanism for transmitting rotation of the first handle shaft to the first moving mechanism;
A second transmission mechanism for transmitting rotation of the second handle shaft to the second movement mechanism;
A connection / release mechanism for connecting or releasing the first handle shaft and the second handle shaft;
A stereomicroscope characterized by comprising: The connection / release mechanism is provided at a tip end portion of the first handle shaft or the second handle shaft, and is a connection for rotatably fitting the tip end portion of the second handle shaft or the first handle shaft. Members,
A restricting member that restricts transmission of rotational motion between the first handle shaft and the second handle shaft in a state where the second handle shaft or the first handle shaft is fitted into the connecting member. When,
The stereomicroscope according to claim 3 or 4, characterized by comprising: The coupling / releasing mechanism is provided on the first handle shaft or the second handle shaft, and a hollow portion that rotatably fits the second handle shaft or the first handle shaft;
A restricting member that restricts transmission of rotational motion between the first handle shaft and the second handle shaft in a state where the second handle shaft or the first handle shaft is fitted in the hollow portion. When,
The stereomicroscope according to claim 3 or 4, characterized by comprising:   The stereomicroscope according to claim 5 or 6, wherein the restricting member fixes or releases the second handle shaft or the first handle shaft fitted into the connecting member.   The stereomicroscope according to claim 7, wherein the restricting member is a screw member that is tightened or loosened with respect to the connecting member by a tool. The first handle shaft and the second handle shaft are provided opposite to each other;
The connection / release mechanism is provided at an intermediate portion between the first handle shaft and the second handle shaft connected to each other.
The stereomicroscope according to claim 5 or 6, characterized in that. The connecting / releasing mechanism provided at an intermediate portion between the first handle shaft and the second handle shaft has a lens body frame having an opening on a front surface that houses the first lens and the second lens. Provided in the
The opening is closed by a front cover;
Operating the restriction member through a hole provided in the front cover to connect or release the first handle shaft and the second handle shaft;
The stereomicroscope according to claim 9. The first handle shaft and the second handle shaft are provided opposite to each other;
The connection / release mechanism is provided on one end side of the connected first handle shaft and the second handle shaft.
The stereomicroscope according to claim 6. The connection / release mechanism is provided on one end side of the first handle shaft or the second handle shaft, and is formed with a diameter larger than the diameter of the first handle shaft or the second handle shaft, It also serves as a handle for changing the magnification for stereoscopically viewing the sample by rotating the first handle shaft or the second handle shaft.
The stereomicroscope according to claim 11. The connection / release mechanism is provided outside a lens frame that houses the first lens and the second lens,
Operating the regulating member outside the lens body frame to connect the first handle shaft and the second handle shaft or to release the connection;
The stereomicroscope according to claim 11 or 12, characterized in that. The first handle shaft or the second handle shaft is formed in a hollow shape, and the second handle shaft or the first handle shaft is formed in the hollow portion of the first handle shaft or the second handle shaft. The handle shaft is inserted rotatably,
The connection / release mechanism is provided on one end side of the first handle shaft or the second handle shaft having the hollow portion and outside the lens frame that houses the first lens and the second lens. A restricting member for restricting transmission of rotational motion between the first handle shaft and the second handle shaft;
The stereomicroscope according to claim 3 or 4, characterized by comprising: The first handle shaft or the second handle shaft is formed in a hollow shape, and the second handle shaft or the first handle shaft is formed in the hollow portion of the first handle shaft or the second handle shaft. A handle shaft is provided to pass through in a rotatable manner,
The connecting / releasing mechanism is provided on one end side of the first handle shaft or the second handle shaft having the hollow portion and outside the lens frame that houses the first lens and the second lens. A restricting member that is provided also as the first handle or the second handle, and that restricts transmission of rotational motion between the first handle shaft and the second handle shaft;
Each first handle is provided at each end of the second handle shaft or the first handle shaft provided penetrating into the hollow portion.
The stereomicroscope according to claim 3 or 4, characterized in that. A first movement restricting member for restricting a moving range of the first lens on the first optical axis by the first moving mechanism;
A second movement regulating member that regulates a movement range of the second lens on the second optical axis by the second movement mechanism;
The movement restriction range by the first movement restriction member is matched with the movement restriction range by the second movement restriction member;
The stereomicroscope according to claim 2, wherein: The interlock switching mechanism connects the first moving mechanism and the second moving mechanism on the first optical axis of the first lens by the moving operation of the first moving mechanism. The position and the position of the second lens on the second optical axis by the movement operation by the second movement mechanism coincide with each other, or a state of each arbitrary position,
The stereomicroscope according to claim 2, wherein:

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